A semiconductor device of an embodiment includes a SiC layer having a surface inclined with respect to a {000-1} face at an angle of 0 to 10 or a surface a normal line direction of which is inclined with respect to a <000-1> direction at an angle of 80 to 90, a gate electrode, an insulating layer at least a part of which is provided between the surface and the gate electrode, and a region, at least apart of which is provided between the surface and the insulating layer, including a bond between carbon and carbon.

A vertical semiconductor device (e.g. a vertical power device, an IGBT device, a vertical bipolar transistor, a UMOS device or a GTO thyristor) is formed with an active semiconductor region, within which a plurality of semiconductor structures have been fabricated to form an active device, and below which at least a portion of a substrate material has been removed to isolate the active device, to expose at least one of the semiconductor structures for bottom side electrical connection and to enhance thermal dissipation. At least one of the semiconductor structures is preferably contacted by an electrode at the bottom side of the active semiconductor region.

A method of manufacturing semiconductor devices in a semiconductor wafer comprises forming charge compensation device structures in the semiconductor wafer. An electric characteristic related to the charge compensation device structures is measured. At least one of proton irradiation and annealing parameters are adjusted based on the measured electric characteristic. The semiconductor wafer is irradiated with protons and annealed based on the at least one of the adjusted proton irradiation and annealing parameters. Laser beam irradiation parameters are adjusted with respect to different positions on the semiconductor wafer based on the measured electric characteristic. The semiconductor wafer is irradiated with a photon beam at the different positions on the wafer based on the photon beam irradiation parameters.

A method of producing a semiconductor device is presented. The method comprises: providing a semiconductor substrate having a surface; epitaxially growing, along a vertical direction (Z) perpendicular to the surface, a back side emitter layer on top of the surface, wherein the back side emitter layer has dopants of a first conductivity type or dopants of a second conductivity type complementary to the first conductivity type; epitaxially growing, along the vertical direction (Z), a drift layer having dopants of the first conductivity type above the back side emitter layer, wherein a dopant concentration of the back side emitter layer is higher than a dopant concentration of the drift layer; and creating, either within or on top of the drift layer, a body region having dopants of the second conductivity type, a transition between the body region and the drift layer forming a pn-junction (Zpn). Epitaxially growing the drift layer includes creating, within the drift layer, a dopant concentration profile (P) of dopants of the first conductivity type along the vertical direction (Z), the dopant concentration profile (P) in the drift layer exhibiting a variation of a concentration of dopants of the first conductivity type along the vertical direction (Z).

First and second transistors with different electrical characteristics are supported by a substrate having a first-type dopant. The first transistor includes a well region within the substrate having the first-type dopant, a first body region within the well region having a second-type dopant and a first source region within the first body region and laterally offset from the well region by a first channel. The second transistor includes a second body region within the semiconductor substrate layer having the second-type dopant and a second source region within the second body region and laterally offset from material of the substrate by a second channel having a length greater than the length of the first channel. A gate region extends over portions of the first and second body regions for the first and second channels, respectively.

A photo relay includes an illuminating unit, a photoelectric conversion IC, a first MOS IC and a second MOS IC. The illuminating unit receives an input signal to generate an illuminating signal. The photoelectric conversion IC receives the illuminating signal to generate a voltage control signal accordingly. The second MOS IC is reversely stacked on the first MOS IC, such that the source electrodes of the two MOS ICs are electrically connected, and the gate electrodes of the two MOS ICs are electrically connected through a gate connection structure for receiving the voltage control signal, and the drain electrodes of the two MOS ICs generate an output signal according to the received voltage control signal.

A semiconductor device is manufactured by forming a gate electrode adjacent to a body region in a semiconductor substrate, forming a field plate trench in a main surface of the substrate, the field plate trench having an extension length in a first direction parallel to the main surface, and forming a field electrode and a field dielectric layer in the field plate trench so that the field electrode is insulated from an adjacent drift zone by the field dielectric layer. The extension length of the field plate trench in the first direction is less than double an extension length of the field electrode in a second direction that is perpendicular to the first direction and is parallel to the main surface. The extension length in the first direction is more than half the extension length in the second direction.

A method of fabricating a semiconductor device includes etching a semiconductor substrate having a top surface to form a trench having sidewalls and a bottom surface that extends from the top surface into the semiconductor substrate. A dielectric liner of a first dielectric material is formed on the bottom surface and sidewalls of the trench to line the trench. A second dielectric layer of a second dielectric material is deposited to at least partially fill the trench. The second dielectric layer is partially etched to selectively remove the second dielectric layer from an upper portion of the trench while preserving the second dielectric layer on a lower portion of the trench. The trench is filled with a fill material which provides an electrical conductivity that is at least that of a semiconductor.

A silicon carbide vertical MOSFET includes an N-counter layer of a first conductivity type formed in a surface layer other than a second semiconductor layer base layer selectively formed in a low concentration layer on a surface of the substrate, a gate electrode layer formed through a gate insulating film in at least a portion of an exposed portion of a surface of a third semiconductor layer of a second conductivity type between a source region of the first conductivity type and the N-counter layer of the first conductivity type, and a source electrode in contact commonly with surfaces of the source region and the third semiconductor layer. Portions of the second conductivity type semiconductor layer are connected with each other in a region beneath the N-counter layer.

Described herein is a semiconductor device including a semiconductor substrate in which an element region and a termination region surrounding the element region are provided. The element region includes: a gate trench; a gate insulating film; and a gate electrode. The termination region includes: a plurality of termination trenches provided around the element region; an inner trench insulating layer located inside of each of the plurality of termination trenches; and an upper surface insulating layer located at an upper surface of the semiconductor substrate in the termination region. The upper surface insulating layer includes a first portion and a second portion having a thinner thickness than the first portion and located at a location separated from the element region than the first portion, and a gate wiring is located at an upper surface of the first portion and is not located at an upper surface of the second portion.